MEMS actuator structures resistant to shock

ABSTRACT

Shock-resistant MEMS structures are disclosed. In one implementation, a motion control flexure for a MEMS device includes: a rod including a first and second end, wherein the rod is tapered along its length such that it is widest at its center and thinnest at its ends; a first hinge directly coupled to the first end of the rod; and a second hinge directly coupled to the second of the rod. In another implementation, a conductive cantilever for a MEMS device includes: a curved center portion includes a first and second end, wherein the center portion has a point of inflection; a first root coupled to the first end of the center portion; and a second root coupled to the second end of the center portion. In yet another implementation, a shock stop for a MEMS device is described.

TECHNICAL FIELD

The present disclosure relates generally to shock resistant structures for microelectromechanical systems (MEMS), and more particularly to shock resistant structures for MEMS actuators.

BRIEF SUMMARY OF THE DISCLOSURE

In accordance with various embodiments of the technology disclosed herein, shock-resistant MEMS device structures are disclosed. In one embodiment, a motion control flexure for a MEMS device includes: a rod comprising a first and second end, wherein the rod is tapered along its length such that it is widest at its center and thinnest at its ends; a first hinge directly coupled to the first end of the rod; and a second hinge directly coupled to the second of the rod. In various implementations of this embodiment, the rod may be between 1 and 4 mm long and between 10 and 70 μm wide, and each of the first and second hinges is between 0.05 and 0.3 mm long and between 1 and 10 μm wide. In particular implementations, the rod is about 50 μm wide at is center and about 35 μm wide at its first and second ends.

In another embodiment, a conductive cantilever for a MEMS device includes a curved center portion comprising a first and second end, wherein the center portion comprises a point of inflection; a first root coupled to the first end of the center portion; and a second root coupled to the second end of the center portion. In various implementations of this embodiment, the total length of the conductive cantilever may be between 4.5 and 7 millimeters, and the center portion may be between 0.012 and 0.030 millimeters wide. In one particular implementation of the conductive cantilever, each of the first and second roots is coupled to the center portion by a respective forked junction in a direction perpendicular to the length of the cantilever. In this implementation, the forked junction includes a plurality of parallel beams. In one embodiment, the forked junction includes a first tapered end coupled to a second tapered end in a direction perpendicular to the length of the cantilever.

In yet another embodiment, a shock stop for a MEMS device is between 0.250 and 1.000 millimeters wide and between 0.0250 and 1.200 millimeters long, and comprises a plurality of circular apertures with a diameter between 10 and 20 micrometers. In one implementation of this embodiment, the shock stop may be used in a MEMS actuator. In this embodiment, the MEMS actuator may include: an inner frame, the inner frame including the shock stop; and an outer frame coupled to the inner frame by a plurality of flexures, wherein the outer frame includes a corresponding shock stop configured to contact the shock stop in the event of a shock.

As used herein, the term “about” in quantitative terms refers to plus or minus 10%. For example, “about 10” would encompass 9-11. Moreover, where “about” is used herein in conjunction with a quantitative term it is understood that in addition to the value plus or minus 10%, the exact value of the quantitative term is also contemplated and described. For example, the term “about 10” expressly contemplates, describes and includes exactly 10.

Other features and aspects of the disclosure will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the features in accordance with various embodiments. The summary is not intended to limit the scope of the invention, which is defined solely by the claims attached hereto.

BRIEF DESCRIPTION OF THE DRAWINGS

The disclosed technology, in accordance with one or more various embodiments, is described in detail with reference to the following figures. The drawings are provided for purposes of illustration only and merely depict typical or example embodiments of the disclosed technology. These drawings are provided to facilitate the reader's understanding of the disclosed technology and shall not be considered limiting of the breadth, scope, or applicability thereof. It should be noted that for clarity and ease of illustration these drawings are not necessarily made to scale.

FIG. 1A illustrates a plan view of a comb drive in accordance with example embodiments of the disclosed technology.

FIG. 1B illustrates a plan view of a bidirectional comb drive actuator including six of the comb drives of FIG. 1A that may use shock-resistant motion control flexures in accordance with embodiments of the disclosed technology.

FIG. 1C is a magnified view of a first comb drive coupled to a second comb drive in accordance with embodiments of the disclosed technology.

FIG. 1D illustrates a tapered motion control flexure for an actuator that may be used in embodiments to absorb an inertial load during shock events.

FIG. 2A illustrates a plan view of an MEMS actuator in accordance with example embodiments of the disclosed technology.

FIG. 2B illustrates a cross-sectional view of a cantilever of the actuator of FIG. 2A in accordance with example embodiments of the disclosed technology.

FIG. 2C illustrates a cantilever having a forked junction design that may be implemented in embodiments of the disclosed technology.

FIG. 2D illustrates a cantilever having an S-shaped design that may be implemented in embodiments of the disclosed technology.

FIG. 2E illustrates a cantilever having an S-shaped design and forked junction that may be implemented in embodiments of the disclosed technology.

FIG. 2F illustrates an alternative embodiment of a forked junction that may be used in the cantilever of FIG. 2E.

FIG. 3A illustrates an example MEMS actuator including an outer frame, inner frame, and shock stops in accordance with the disclosed technology.

FIG. 3B is a magnified view of the latching mechanisms and shock stops of the MEMS actuator of FIG. 3A.

FIG. 3C illustrates a pair of shock stops that may be implemented in embodiments of the disclosed technology.

FIG. 3D illustrates a shock stop that may be implemented in embodiments of the disclosed technology.

FIG. 4 is an exploded perspective view of an example image sensor package utilized in accordance with various embodiments of the disclosed technology.

The figures are not intended to be exhaustive or to limit the invention to the precise form disclosed. It should be understood that the invention can be practiced with modification and alteration, and that the disclosed technology be limited only by the claims and the equivalents thereof.

DETAILED DESCRIPTION

In accordance with various embodiments of the disclosed technology, shock-resistant MEMS device structures are disclosed. More particularly, FIGS. 1-4 illustrate MEMS actuators for moving an optoelectronic device that may implement shock-resistant MEMS structures in accordance with particular embodiments of the technology disclosed herein. In implementations, the shock-resistant structures described herein may reduce load on the MEMS actuator and resist deformation during events (e.g., dropping the MEMS actuator) that may cause shock to the MEMS actuator. It should be noted that although the shock resistant MEMS actuator structures will be described primarily with reference to the example MEMS actuators of FIGS. 1-4, one having skill in the art would appreciate that the shock-resistant structures could be implemented in other MEMS apparatuses including moving parts that may be subject to shock events.

FIGS. 1A-1B illustrate plan views of a comb drive 10 and bidirectional comb drive actuator 20 including six comb drives 10 a-f in accordance with example embodiments of the present disclosure. As illustrated in FIG. 1A, each comb drive 10 includes comb finger arrays 15 and 16. Each comb finger array 15 and 16 includes a respective spine (14, 12) and plurality of comb fingers (13, 11).

Bidirectional Comb drive actuator 20 includes first and second frame pieces 22 a-22 b, and first and second motion control flexures 24 a-24 b. Although not shown in detail in FIG. 1B, it will be understood that, as shown in FIG. 1A, for each comb drive 10 a-f, comb fingers 11 and 13 extend substantially from left to right, and vice versa, in comb finger arrays 15 a-f and 16 a-f. Moreover, it will be understood that spines 12 and 14 run substantially vertically from first frame piece 22 a to second frame piece 22 b, i.e., substantially in parallel with motion control flexures 24 a-24 b. This is illustrated by FIG. 1C, which shows a first comb drive 10 b coupled to a second comb drive 10 c.

As illustrated in this embodiment, spine 14 is attached to second frame piece 22 b, while spine 12 is attached to first frame piece 22 a. During operation, as comb finger arrays 15 and 16 of each comb drive 10 a-10 f are attracted to or repelled from one another by electrostatic forces, movement occurs such that first frame piece 22 a likewise moves in a direction when the second frame is fixed (e.g., in the positive X direction in FIG. 1B). One of skill in the art will appreciate, upon studying the present disclosure, that electrostatic forces and other motive forces may be developed between each pair of comb finger arrays 15 and 16 by methods other than applying voltage, without departing from the spirit of the present disclosure. For example, charge may be applied to comb finger arrays 15 and 16.

In various embodiments, spines 12 and 14 and first and second frame pieces 22 a and 22 b may be dimensioned wide and deep enough to be rigid and not flex substantially under an applied range of electrostatic or other motive forces. For example, in particular embodiments spines 12 and 14 may be about 20 to 100 micrometers wide and about 50 to 250 micrometers deep, and first and second frame pieces 22 a and 22 b may be larger than about 50 micrometers wide and about 50 to 250 micrometers deep.

In one embodiment, during operation of comb drive actuator 20, when comb finger arrays 15 a and 16 a are electrified (e.g., in the manner described above), a motive force is applied with respect to first and second frame pieces 22 a-22 b such that either first or second frame piece 22 a-22 b moves substantially horizontally from an initial position with respect to second or first frame piece 22 a-22 b, depending upon which of first and second frame piece 22 a-22 b is mechanically fixed. Once comb finger arrays 15 a and 16 a are no longer electrified, first or second frame pieces 22 a-22 b move back to the initial state due to the spring restoring force of first and second motion flexures 24 a and 24 b. Further to this implementation, movement in a substantially opposite direction is achieved (e.g., in the opposite X direction in FIG. 1B), in addition to the movement resulting from comb drive 10 a, when comb finger arrays 15 c and 16 c of comb drive 10 c are electrified. Likewise, bidirectional movement in these two directions (i.e., positive and negative X direction in the drawing) may be achieved by electrifying the comb finger arrays of comb drives 10 b, 10 d, and 10 e-f.

In various embodiments, spines 12 and 14 of comb finger arrays 15 a-f and 16 a-f may be attached to first and/or second frame pieces 22 a-b in different configurations to achieve different purposes. For example, in one embodiment, for each comb drive 10 a-10 f, spine 12 is attached to first frame piece 22 a while spine 14 is attached to second frame piece 22 b. Such a configuration results in a parallel cascade of comb drives 10 a-f that may increase the electrostatic force ultimately applied to first and second frame pieces 22 a-b. In another example embodiment, comb drives 10 a-10 f are arranged in a back-to-back fashion to achieve bidirectional movement, as described above. While this back-to-back arrangement was described above with regard comb drives 10 a-f—i.e., six comb drives 10—a different number of comb drives may be used to achieve bidirectional movement.

In one embodiment, a comb finger array, for example, 16 a, 16 c, 16 e or 15 b, 15 d, 15 f of each comb drive 10 a-10 f may be tied to a common potential (e.g., ground or some other positive or negative voltage) that acts as a reference for the other three comb finger arrays. Given this reference, the comb finger arrays that are not tied to a common potential may be electrified depending upon the direction of movement required.

For example, consider an embodiment where comb finger arrays 15 a, 16 b, 15 c, 16 d, 15 e and 15 f of comb drives 10 a-10 f are tied to a common ground. In this embodiment, movement of comb drive actuator 20 may be effectuated by applying a positive or negative voltage (e.g., relative to ground or other common reference) to comb finger array 16 a, hence causing comb finger array 16 a to be attracted to comb finger array 15 a. Assuming second frame piece 22 b is fixed, this attraction would, in this example, cause first frame piece 22 a to move to the left in FIG. 1B. Further to this illustration, electrifying comb finger array 15 b may entail applying thereto a positive or negative voltage 15 b, hence causing comb finger array 15 b to be attracted to comb finger array 16 b. This attraction would, in this instance, cause first frame piece 22 a to move to the right in FIG. 1B, assuming again that second frame piece 22 b is fixed.

In further embodiments, the motive force developed by a comb drive 10 a may differ from the motive force developed by another comb drive 10 b-10 f. For example, voltages of different magnitudes may be applied to some or all of comb finger arrays 15 b, 15 d, and 15 f, or whichever comb finger arrays are not tied to a common potential. In some embodiments, for comb finger arrays 15 b, 15 d, and 15 f to maintain different voltage levels, or electrostatic or charge states, the comb finger arrays may be electrically separate (or isolated) from one another.

The movement of first or second frame pieces 22 a-22 b and comb finger arrays 15 a-f or 16 a-f of each comb drive 10 a-10 f may be directed and/or controlled to some extent by first and second motion control flexures 24 a-24 b. In this particular embodiment, for example, first and second motion control flexures 24 a-24 b are substantially flexible or soft in the horizontal direction (i.e., in the direction of comb fingers 11 and 13) and substantially stiff or rigid in the vertical direction (i.e., in the direction of spines 12 and 14). Accordingly, first and second motion control flexures 24 a-24 b allow comb drive 10 to effect bidirectional movement horizontally (i.e., in the X direction FIG. 1B) while substantially restricting the movement in the vertical direction (i.e., in the Y direction in FIG. 1B).

The arrangement of first and second motion control flexures 24 a-24 b may be referred to, in some embodiments, as a double parallel flexure motion control. Such a double parallel flexure motion control may produce nearly linear motion, but there may be a slight run-out known as arcuate motion. Nevertheless, the gap on one side of comb fingers 11 may not be equal to the gap on the other side of comb fingers 11, and this may be used advantageously in design to correct for effects such as arcuate motion of a double parallel flexure motion control. In embodiments, additional structures may be used to control the motion of first and second frame pieces 22 a-22 b with respect to one another.

In the illustrated embodiment, first and second flexures 24 a-24 b include thinner portions 24 a-2 and 24 b-2 on the respective ends thereof. These thinner portions may allow bending when, for example, there is a translation of first frame piece 22 a with respect to second frame piece 22 b or vice versa (i.e., in the X direction in FIG. 1B). In embodiments, thinner portions 24 a-2 and 24 b-2 may be shaped as Y-junctions to add flexibility that permits motion in the X direction. In embodiments, the thicker portion 24 a-1 and 24 b-1 of first and second flexures 24 a and 24 b may be dimensioned to be about 10 to 50 micrometers (μm) wide (i.e., width in x direction of FIG. 1B), and the thinner portions 24 a-2 and 24 b-2 may be dimensioned to be about 1 to 10 μm wide. In various embodiments, any number and type of motion controls may be used as desired to control or limit the motion of comb finger arrays 15 or 16. Controlled motion may enhance the overall precision with which comb drive actuator 20 effects movement, or positions a device such as, for example, an image sensor in a smartphone camera. In addition, controlled motion aids in avoiding a situation in which comb fingers 11 and 13 snap together. For example, controlled motion may generally be effected by creating a lower level of stiffness in desired direction of motion of comb fingers 15 and 16, while creating a higher level of stiffness in the direction orthogonal to the motion of comb fingers 15 and 16 in the plane of comb drive actuator 20. By way of example, this may be done using a double parallel flexure type motion control.

In various embodiments, motion control flexures 24 a and 24 b may be designed to improve the shock performance of a MEMS actuator device. In such embodiments, motion control flexures 24 a and 24 b may be designed to absorb a force or load during a shock event (e.g., dropping a device containing the MEMS actuator). For example, in particular embodiments, motion control flexures 24 a and 24 b may be designed to absorb the inertial load due to a motion stage for the MEMS actuator (not illustrated) and at least one of the three comb array pairs (10 a, 10 c, 10 e), and (10 b, 10 d, 10 f). In specific implementations of these embodiments, this inertial load may be between 200 and 800 mN.

FIG. 1D illustrates a particular design for a tapered motion control flexure 24 that may be used in embodiments to absorb an inertial load during shock events. In embodiments, motion control flexure 24 may absorb a loading force between 100 and 400 mN before entering a buckled state (i.e., before deforming).

As shown, motion control flexure 24 includes two thin, soft hinges 24-2 and a wide, stiff rod 24-1 connecting the two hinges. In embodiments, rod 24-1 may be between 1 and 4 millimeters (mm) long in the x direction and between 10 and 50 μm wide in the y direction. In embodiments, hinges 24-2 may be between 0.05 and 0.3 mm long in the x direction and between 1 and 10 μm wide in the y direction. In these embodiments, the dimensions of hinges 24-2 may be optimized to achieve a required stiffness or to avoid buckling. As shown in this particular embodiment, rod 24-1 is tapered along its length such that it is widest at its center and thinnest at it ends. This tapered design, in some embodiments, permits motion control flexure 24 to absorb a larger loading force before entering a buckled state. In particular implementations of this embodiment, tapered rod 24-1 may be between 35 and 50 μm wide at its center and between 20 and 40 μm wide at its ends. In one particular embodiment, stiff-rod 24-1 is about 50 μm wide at its center, about 35 μm wide at its end, and capable of absorbing an inertial load of about 280 mN before buckling. In alternative embodiments, stiff-rod 24-1 may be uniformly wide along its entire length.

FIG. 2A illustrates a plan view of an example MEMS multi-dimensional actuator 40 in accordance with example embodiments of the present disclosure. As illustrated in this embodiment, actuator 40 includes an outer frame 48 (divided into four sections) connected to inner frame 46 by one or more spring elements or flexures 80, four bidirectional comb drive actuators 20 a-d, and one or more cantilevers 44 a-d including a first end connected to one end of comb drive actuators 20 a-d and a second end connected to inner frame 46. Although FIG. 2A illustrates an example actuator 40 including four comb drive actuators 20, in other embodiments, actuator 40 may include a different number of comb drive actuators 20.

In embodiments, actuator 40 includes an anchor 42 that is rigidly connected or attached to first and/or second frame pieces 22 a-22 b of one or more comb drive actuators 20, such that anchor 42 is mechanically fixed with respect thereto. Thus, for example, if first frame piece 22 a is attached to anchor 42, movement of second frame piece 22 b relative to first frame piece 22 a may also be considered movement relative to anchor 42.

During operation of actuator 40, comb drive actuators 20 a-d may apply a a controlled force between inner frame 46 and anchor 42. One or more comb drive actuators 20 a-d may be rigidly connected or attached to anchor 42, and anchor 42 may be mechanically fixed (e.g., rigidly connected or attached) with respect to outer frame 48. In one embodiment, a platform is rigidly connected or attached to outer frame 48 and to anchor 42. In this manner, the platform may mechanically fix outer frame 48 with respect to anchor 42 (and/or vice versa). Inner frame 46 may then move with respect to both outer frame 48 and anchor 42, and also with respect to the platform. In one embodiment, the platform is a silicon platform. The platform, in various embodiments, is an optoelectronic device, or an image sensor, such as a charge-coupled-device (CCD) or a complementary-metal-oxide-semiconductor (CMOS) image sensor.

In embodiments, the size of actuator 40 may be substantially the same as the size as the platform, and the platform may attach to outer frame 48 and anchor 42, thus mechanically fixing anchor 42 with respect to outer frame 48. In another embodiment of actuator 40, the platform is smaller than actuator 40, and the platform attaches to inner frame 46. In this particular embodiment, outer frame 48 is fixed (or rigidly connected or attached) relative to anchor 42, and inner frame 46 is moved by the various comb drive actuators 20 a-d.

In one embodiment, two comb drive actuators 20 a and 20 d actuate along a first direction or axis in the plane of actuator 40 (e.g., east/west, or left/right), and two comb drive actuators 20 b and 20 c actuate along a second direction or axis in the plane of actuator 40 (e.g., north/south, or top/bottom). The first and second directions may be substantially perpendicular to one another in the plane of actuator 40.

Various other configurations of comb drive actuators 20 a-d are possible. Such configurations may include more or less comb drives 10 in each of the comb drive actuators 20 a-d, and various positioning and/or arrangement of comb drive actuators 20 a-d, for example, to enable actuation in more or less degrees of freedom (e.g., in a triangular, pentagonal, hexagonal formation, or the like).

In embodiments, cantilevers 44 a-d are relatively stiff in the respective direction of motion of the respective comb drive actuators 20 a-d, and are relatively soft in the in-plane orthogonal direction. This may allow for comb drive actuators 20 a-d to effect a controlled motion of inner frame 46 with respect to anchor 42 and hence with respect to outer frame 48. In embodiments, illustrated by FIG. 2A, outer frame 48 is not continuous around the perimeter of actuator 40, but is broken into pieces (e.g., two, three, four, or more pieces). Alternatively, in other embodiments, outer frame 48 may be continuous around the perimeter of actuator 40. Similarly, inner frame 46 may be continuous or may be divided into sections.

In various embodiments, electrical signals may be delivered to comb drive actuators 20 a-d via routing on or in cantilevers 44 a-d. In some instances, two or more different voltages may be used in conjunction with comb drive actuator 20 a. In such instances, two electrical signals may be routed to comb drive actuator 20 a via first and second conductive layers 45 and 47, respectively, of cantilever 44 a. Once delivered to comb drive actuator 20 a, the two electrical signals may be routed, for example, via first frame piece 22 a, to comb finger arrays 16 a and 15 b, respectively.

In another example implementation of actuator 40, two electrical signals used to develop motive forces in comb drive actuator 20 b may also be used to develop similar motive forces in comb drive actuator 20 c. In such an implementation, rather than routing these two electrical signals to comb drive actuator 20 c through cantilever 44 c, the two electrical signals may be routed to comb drive actuator 20 c from comb drive actuator 20 b. By way of example, this may entail routing the two electrical signals from an electrical contact pad 84, through cantilever 44 b to a first frame piece 22 a of comb drive actuator 20 b. In addition, the two electrical signals may be routed from first frame piece 22 a via flexures 24 a-b (respectively) and second frame piece 22 b to anchor 42. The two electrical signals may then be routed through anchor 42 to comb drive actuator 20 c. It will be appreciated that various routing options may be exploited to deliver electrical signals to comb drive actuators 20 a-d. For example, multiple routing layers may be utilized in anchor 42, in first or second frame pieces 22 a/b, and/or in first and second flexures 24 a/b.

FIG. 2B illustrates a cross-sectional view of a portion of a cantilever 44 in accordance with example embodiments of the present disclosure. As illustrated in FIG. 2B, cantilever 44 includes first and second conductive layers 45 and 47, and first and second insulating layers 43 and 49. First and second conductive layers 45 and 47 may, in some example implementations, serve as routing layers for electrical signals, and may include poly silicon and/or metal. Insulating layers 43 and 49 may provide structure for first and second conductive layers 45 and 47. In alternative embodiments of cantilever 44, the order of the conductive and insulating layers may be switched such that layers 43 and 49 are conductive layers and layers 45 and 47 are insulating layers.

In one example implementation of cantilever 44, insulating layers 43 and 49 include silicon dioxide, second conductive layer 47 includes metal, and first conductive layer 45 includes polysilicon. In a variant of this example, a coating (e.g., oxide or the like) may cover second conductive layer 47, e.g., to provide insulation against shorting out when coming into contact with another conductor. Second insulating layer 49 may be a thin layer that includes oxide or the like. Additionally, first conductive layer 45, in some instances, may be relatively thick (compared to the other layers of cantilever 44), and may, for example, include silicon, polysilicon, metal, or the like. In such instances, first conductive layer 45 may contribute more than the other layers to the overall characteristics of cantilever 44, including, for example, the nature, degree, or directionality of the flexibility thereof.

Additional embodiments of cantilever 44 (and cantilevers 44 a-d) may include additional conductive layers, such that additional electrical signals may be routed via the cantilever 44. In some embodiments, cantilevers 44 a-d may be manufactured in a similar fashion to flexures 24 a-24 b, though the sizing may be different between the two. Moreover, as would be appreciated by one having skill in the art, additional materials may be used to form the various layers of cantilever 44.

In various embodiments, outer cantilevers 44 may be designed to be resistant to shock events (e.g., in the event a device including MEMS actuator 40 is dropped). In such embodiments, each cantilever 44 may be designed such that it i) experiences less displacement stress during shock; ii) experiences less radial stiffness during shock; and iii) withstands a high load without buckling. In some embodiments, outer cantilevers 44 may be designed such that they experience a peak stress of less than about 1900 MPa along their length, and less than about 2100 MPa along their width, in the event of a shock FIGS. 2C-2F illustrate four example designs of shock-resistant outer cantilevers that may be implemented in embodiments of the disclosure.

FIG. 2C illustrates an outer cantilever 44 e having a forked junction design. As shown, cantilever 44 e includes a forked junction 44 e-1 at its center. The forked-junction 44 e-1 at the center includes an aperture 44 e-2 and is wider (in Y direction) than the sides 44 e-3 of outer cantilever 44 e. In various embodiments, the width (in Y direction) of aperture 44 e-2 is between 0.02 and 0.04 millimeters, the maximum width of the forked junction 44 e-1 is between 0.06 and 0.12 millimeters, and the width of sides 44 e-3 is between 0.012 and 0.050 millimeters. In further embodiments, the total length (in X direction) of cantilever 44 e is between 4.5 and 7 millimeters. In alternative embodiments, cantilever 44 e may include additional forks (and hence apertures) at its center (e.g. 3, 4, etc.).

FIG. 2D illustrates an outer cantilever 44 f having an S-shaped design. It should be noted that although cantilever 44 f primarily appears straight along its length in FIG. 2D, it is curved and has a point of inflection (hence the “S-shape”) along its length that improves resilience in the event of a shock by adding flexibility to cantilever 44 f. In this embodiment, the two roots or connecting ends 44 f-1 of cantilever 44 f couple to a center portion 44 f-3 via a thinner portion 44 f-2. Cantilever 44 f is widest (in Y direction) at its roots 44 f-1 and thinnest at the junction 44 f-2 between roots 44 f-1 and center portion 44 f-3. In various embodiments, the total length (x1) of cantilever 44 f is between 4.5 and 7 millimeters, and the width (y1) of center portion 44 f-3 is between 0.012 and 0.030 millimeters.

FIG. 2E illustrates an outer cantilever 44 g having the S-shaped design of cantilever 44 f and the added feature of a “toothbrush” shaped or forked junction 44 g-1 at each end for relieving stress on cantilever 44 g. As illustrated, outer cantilever 44 g includes a center portion 44 g-3 with ends coupled to end portions 44 g-4 that attach to roots 44 g-2. In various embodiments, the total length (x1) of cantilever 44 g is between 4.5 and 7 millimeters, and the width (y2) of center portion 44 g-3 is between 0.012 and 0.030 millimeters.

The forked junction 44 g-1 couples each end of center portion 44 g-3 to a respective end portion 44 g-4 in a direction perpendicular (i.e., Y direction) to the length of cantilever 44 g. Each junction 44 g-1 includes a plurality of beams 44 g-5 that give the junction 44 g-1 the appearance of a toothbrush. Although each junction 44 g-1 is illustrated as having nine beams 44 g-5 in this embodiment, in alternative embodiments the number of beams 44 g-5 may be decreased or increased (e.g., from 2 to 12) to improve the performance of cantilever 44 g during a shock event (e.g., by reducing peak stress). As illustrated in this particular embodiment, in one junction the end portion 44 g-4 is below (Y direction) its corresponding center portion 44 g-3, and in the other junction the end portion 44 g-4 is above (Y direction) its corresponding center portion 44 g-3. Also illustrated in this particular embodiment, the root 44 g-2 attached to the end portion 44 g-4 below the center portion 44 g-3 points upward, whereas the other root 44 g-2 points downward. In particular embodiments, the total width (y1) of a forked junction 44 g-1, including the end of center portion 44 g-3, end portion 44 g-4, and beams 44 g-5, is between 0.040 and 0.150 millimeters.

FIG. 2F illustrates an alternative embodiment of a forked junction 44 g-1′ that may be used in place of forked junction 44 g-1 in cantilever 44 g to relieve stress. As illustrated in this particular implementation, the end 44 g-3′ of the center portion of cantilever 44 g is tapered along its length (X direction) such that its width (Y direction) decreases in a direction toward root 44 g-2′. End 44 g-3′ attaches to a corresponding tapered end portion 44 g-4′ that is tapered along its length such that's width decreases in a direction away from root 44 g-2′. Because the width (Y direction) of ends 44 g-3′ and 44 g-4′ is substantially less along their junction point, this tapered design permits a greater length of beams 44 g-5′ in a direction roughly perpendicular to cantilever 44 g (Y direction). In this embodiment, the root 44 g-2′ is shaped as a Y junction extending in a direction parallel to cantilever 44 g (X direction).

Referring back to FIG. 2A, actuator 40 includes one or more flexures or spring elements 80 connecting inner frame 46 to outer frame 48. Flexures 80 may be electrically conductive and may be soft in all movement degrees of freedom. In various embodiments, flexures 80 route electrical signals between electrical contact pads 82 on outer frame 48 to electrical contact pads 84 on inner frame 46. These electrical signals may subsequently be routed to one or more comb drive actuators 20 through one or more cantilevers 44 a-44 d. In example implementations, flexures 80 come out from inner frame 46 in one direction, two directions, three directions, or in all four directions.

In one embodiment, actuator 40 is made using MEMS processes such as, for example, photolithography and etching of silicon. Actuator 40, in some cases, moves +/−150 micrometers in plane, and flexures 80 may be designed to tolerate this range of motion without touching one another (e.g., so that separate electrical signals can be routed on the various spring elements 80). For example, flexures 80 may be S-shaped flexures ranging from about 1 to 5 micrometers in thickness, about 2 to 40 micrometers wide, and about 150 to 1000 micrometers by about 150 to 1000 micrometers in the plane.

In order for flexures 80 to conduct electricity well with low resistance, flexures 80 may contain, for example, heavily doped polysilicon, silicon, metal (e.g., aluminum), a combination thereof, or other conductive materials, alloys, and the like. For example, flexures 80 may be made out of polysilicon and coated with a roughly 2000 Angstrom thick metal stack of Aluminum, Nickel, and Gold. In one embodiment, some flexures 80 are designed differently from other flexures 80 in order to control the motion between outer frame 48 and inner frame 46. For example, four to eight (or some other number) of flexures 80 may have a device thickness between about 50 and 250 micrometers. Such a thickness may somewhat restrict out-of-plane movement of outer frame 48 with respect to inner frame 46.

In various embodiments, flexures 80 are low stiffness flexures that operate in a buckled state without failure, thereby allowing the stiffness of the flexures to be several orders of magnitude softer than when operated in a normal state. In these embodiments, a buckled section (i.e., flexible portion) of flexures 80 may be designed such that a cross section of the flexible portion along its direction of bending (i.e., thickness and width) is small, while its length is relatively long. Particular embodiments of flexures 80 are described in greater detail in U.S. patent application Ser. No. 14/677,730 titled “Low Stiffness Flexure”, filed Apr. 2, 2015, which is incorporated herein by reference in its entirety.

As noted above with respect to FIG. 2A, a MEMS actuator may be designed with an outer frame 48 coupled to an inner frame 46 by a plurality of buckled flexures 80. During operation, inner frame 46 may collide with outer frame 48 in the event of a sudden shock. Accordingly, in embodiments, shock stops may be included in the outer and inner frames to protect the MEMS actuator structure in the event of shock.

FIGS. 3A-3B illustrate one such embodiment of a MEMS actuator 100 including shock stops. As illustrated in this particular embodiment, MEMS actuator 100 comprises an inner frame 110 coupled to an outer frame 120 by a plurality of buckled flexures (not pictured). Outer frame 120 includes four latched electrical bars 121-124. As illustrated, for each of the connections between the latched bars 121-124, a latch protrusion 125A of a latching mechanism 125 is engaged with a respective groove of a latching mechanism 126, thereby securing the electrical bars 121-124 together. Particular methods of latching an outer frame structure of a MEMS actuator during assembly of the MEMS actuator are described in greater detail in U.S. patent application Ser. No. 14/819,413 titled “Electrical Bar Latching for Low Stiffness Flexure MEMS Actuator”, filed Aug. 5, 2015, which is incorporated herein by reference in its entirety.

Also, illustrated in FIGS. 3A-3B is a pair of shock stops 127 and 111 corresponding to outer frame 120 and inner frame 110, respectively. In this particular embodiment of actuator 100, four pairs of shock stops 127 and 111 (one for each corner) are present to absorb shock collisions between outer frame 120 and inner frame 110 in the event of a shock. However, as would be appreciated by one having skill in the art, any number of shock stop pairs could be implemented in alternative implementations of a MEMS actuator or other MEMS device that experiences collisions between two portions of the device.

In various embodiments, shock stops 127 and 111 may be designed to maximize the amount of kinetic energy they can absorb upon impact (e.g., when horizontal or vertical stop 127 collides with stop 111) due to a shocking event without experiencing permanent deformation. For example, in embodiments shock stops 127 and 111 may be designed to absorb a combined kinetic energy of between 100 and 400 μJ. In particular embodiments, shock stops 127 and 111 may absorb a combined kinetic energy of between 300 and 400 μJ.

FIGS. 3C-3D illustrates two exemplary designs of shock stops 127 and 111 that may be implemented in embodiments of the technology disclosed herein. FIG. 3C illustrates shock stops 127 a and 111 a comprising a plurality of circular, staggered apertures 160. In the event of a shock, surface 127 a-2 of stop 127 a contacts surface 111 a-2 of shock 111 a. As illustrated in this particular embodiment, the apertures 160 are spaced apart in a concentrated, hexagonal pattern. In various embodiments, the diameters of the circular apertures may be between 0.010 and 0.022 millimeters. In particular embodiments, the diameter of the circular apertures is about 16 um. In particular embodiments, shock stops 127 a and 111 a may absorb a combined energy of about 350 μJ and each deform up to about 40 μm before breaking. In alternative implementations of shock stops 127 a and 11 a, apertures 160 may be filled with epoxy glue to adjust their stiffness and/or arranged in a different pattern (e.g., triangular, rectangular, linear, or other pattern). In various embodiments, the total length (x₁) of shock stop 127 a is between 0.250 and 1.000 millimeters, and the total width (y₁) of shock stop 127 a is between 0.0250 and 1.000 millimeters. In various embodiments, the total length (x₂) of shock stop 111 a is between 0.300 and 1.200 millimeters, and the total width (y₂) of shock stop 111 a is between 0.0250 and 1.000 millimeters.

FIG. 3D illustrates a shock stop 127 b comprising a plurality of square, staggered apertures 170. Although a second corresponding shock stop is not illustrated in the example of FIG. 3D, it would be understood by one having skill in the art that the same features of shock stop 127 b could be implemented in the corresponding shock stop. Similar to FIG. 3C, the apertures 170 are spaced apart in a concentrated, hexagonal pattern. In particular embodiments, shock stop 127 b and a corresponding shock stop may absorb a combined energy of about 300 μJ and each deform up to about 15 μm before breaking. In alternative implementations of shock stop 127 b, apertures 170 may be filled with epoxy glue to adjust their stiffness and/or arranged in a different pattern (e.g., triangular, rectangular, linear, or other pattern).

In yet further embodiments of the technology disclosed herein, other alternative shock stop designs may be implemented to tune the maximum energy they can absorb and the maximum amount of distance they may displace without breaking. For example, horizontal or vertical slits may be used instead of or in combination with the aforementioned apertures.

FIG. 4 is an exploded perspective view illustrating an assembled moving image sensor package 55 that may use the actuators described herein in accordance with one embodiment of the technology disclosed herein. Moving image sensor package 55 can include, but is not limited to the following components: a substrate 73; a plurality of capacitors or other passive electrical components 68; a MEMS actuator driver 69; a MEMS actuator 57; an image sensor 70; an image sensor cap 71; and an infrared (IR) cut filter 72. Substrate 73 can include a rigid circuit board 74 with an opening 65 and in-plane movement limiting features 67, and a flexible circuit board acting as a back plate 66. The rigid circuit board 74 may be constructed out of ceramic or composite materials such as those used in the manufacture of printed circuit boards (PCB), or some other appropriate material(s). Moving image sensor package 15 may include one or more drivers 69.

Since the thermal conduction of air is roughly inversely proportional to the gap, and the image sensor 70 can dissipate a substantial amount of power between 100 mW and 1 W, the gaps between the image sensor 30, the stationary portions of the MEMS actuator 57, the moving portions of the MEMS actuator 57, and the back plate 66 are maintained at less than approximately 50 micrometers. In one embodiment, the back plate 66 can be manufactured out of a material with good thermal conduction, such as copper, to further improve the heat sinking of the image sensor 70. In one embodiment, the back plate 66 has a thickness of approximately 50 to 100 micrometers, and the rigid circuit board 74 has a thickness of approximately 150 to 200 micrometers.

While various embodiments of the present invention have been described above, it should be understood that they have been presented by way of example only, and not of limitation. Likewise, the various diagrams may depict an example architectural or other configuration for the invention, which is done to aid in understanding the features and functionality that can be included in the invention. The invention is not restricted to the illustrated example architectures or configurations, but the desired features can be implemented using a variety of alternative architectures and configurations. Indeed, it will be apparent to one of skill in the art how alternative functional, logical or physical partitioning and configurations can be implemented to implement the desired features of the present invention. Also, a multitude of different constituent module names other than those depicted herein can be applied to the various partitions. Additionally, with regard to flow diagrams, operational descriptions and method claims, the order in which the steps are presented herein shall not mandate that various embodiments be implemented to perform the recited functionality in the same order unless the context dictates otherwise.

Although the invention is described above in terms of various exemplary embodiments and implementations, it should be understood that the various features, aspects and functionality described in one or more of the individual embodiments are not limited in their applicability to the particular embodiment with which they are described, but instead can be applied, alone or in various combinations, to one or more of the other embodiments of the invention, whether or not such embodiments are described and whether or not such features are presented as being a part of a described embodiment. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments.

Terms and phrases used in this document, and variations thereof, unless otherwise expressly stated, should be construed as open ended as opposed to limiting. As examples of the foregoing: the term “including” should be read as meaning “including, without limitation” or the like; the term “example” is used to provide exemplary instances of the item in discussion, not an exhaustive or limiting list thereof; the terms “a” or “an” should be read as meaning “at least one,” “one or more” or the like; and adjectives such as “conventional,” “traditional,” “normal,” “standard,” “known” and terms of similar meaning should not be construed as limiting the item described to a given time period or to an item available as of a given time, but instead should be read to encompass conventional, traditional, normal, or standard technologies that may be available or known now or at any time in the future. Likewise, where this document refers to technologies that would be apparent or known to one of ordinary skill in the art, such technologies encompass those apparent or known to the skilled artisan now or at any time in the future.

The presence of broadening words and phrases such as “one or more,” “at least,” “but not limited to” or other like phrases in some instances shall not be read to mean that the narrower case is intended or required in instances where such broadening phrases may be absent. The use of the term “module” does not imply that the components or functionality described or claimed as part of the module are all configured in a common package. Indeed, any or all of the various components of a module, whether control logic or other components, can be combined in a single package or separately maintained and can further be distributed in multiple groupings or packages or across multiple locations.

Additionally, the various embodiments set forth herein are described in terms of exemplary block diagrams, flow charts and other illustrations. As will become apparent to one of ordinary skill in the art after reading this document, the illustrated embodiments and their various alternatives can be implemented without confinement to the illustrated examples. For example, block diagrams and their accompanying description should not be construed as mandating a particular architecture or configuration. 

What is claimed is:
 1. A MEMS actuator, comprising: an inner frame, the inner frame comprising a first shock stop; and an outer frame coupled to the inner frame by a plurality of flexures, wherein the outer frame comprises a second shock stop configured to contact the first shock stop in the event of a shock; wherein the first shock stop and second shock stop each comprise a plurality of apertures, and wherein at least one aperture of the plurality of apertures contains a material to adjust stiffness of the at least one aperture.
 2. The MEMS actuator of claim 1, wherein the apertures are circular and wherein the diameter of the apertures is between 10 and 20 um.
 3. The MEMS actuator of claim 1, wherein: the inner frame comprises a third shock stop; the outer frame comprises a fourth shock stop configured to contact the third shock stop in the event of a shock; and the third shock stop and fourth shock stop each comprise a plurality of apertures.
 4. The MEMS actuator of claim 1, wherein the apertures are spaced part in a hexagonal pattern.
 5. A shock stop for a microelectromechanical systems (MEMS) device, comprising: a plurality of circular apertures with a diameter between 10 and 20 micrometers, wherein the shock stop is between 0.250 and 1.000 millimeters wide and between 0.0250 and 1.200 millimeters long, and wherein at least one aperture of the plurality of apertures contains a material to adjust stiffness of the at least one aperture.
 6. The shock stop of claim 5, wherein at least one aperture of the plurality of apertures is one of circular and a shape other than circular.
 7. The shock stop of claim 5, wherein the material includes epoxy glue.
 8. The MEMS actuator of claim 1, wherein the material includes epoxy glue.
 9. The MEMS actuator of claim 1, wherein at least one aperture of the plurality of apertures is one of circular and a shape other than circular. 